Machine-tool organization



2 Sheets-Sheet INVENToR.

ATTORNEY.

Jaz/ODM J. B. ARMITAGE MACHINE TOOL ORGANIZATION Filed July 29, 1925 April 30, 1929.

April 30, 1 B, ARMlTAGE 1,710,913

MAGHINE TOOL ORGANIZATION Filed July 29, 1925 .2 Sheets-Sheet 2 BYA ATTORNEY.

jouy aiNx/ENR.

llll

Patented Apr. 30, 1929.

UNITED STATES JOSEPH B. ARIMITAGE, OF MILWAUKEE,

- TRECKER CORPORATION, OF WEST ALLIS, WISCONSIN.

MAOHINE-TOOL Application led July 29,

same reference characters are used to desig-f nate tho same partswherever they may appear in each of the several views, Fig. 1 is an elevation of a millingmachine, a part being broken away, and parts being shown in section; .Fig 2 is an elevation of parts, parts being shown in section; Fig. 3 is an end elevation of a part, some other parts being shown in section; Fig. et is a section taken on the line 4:4 on Fig. 3, looking in the direction indicated by the arrows; Fig. 5 is a section taken on the line 5-5 on Fig. l, looking in the direction indicated by the arrows; and Fig. 6 is a section taken on the line 6 6 on Fig. 1, looking in the direction indicated by the arrows.

It is frequently desirable that, in designing machine tools, the organization, construction, and principle of operation of one or more parts be such that the direction of rotation or rotations shall be the same whether the main drive rotates a driven member in -one direction or the other. A milling machine, for example, may be designed and constructed so that its main drive rotates clockwise. If such a` machine were to be placed in a machine shop in a position with respect to a line shaft, forexample, so that a belt would not'run the milling machine in the single direction in which it was ldesigned to be run, the milling machine would have to be run with a crossed belt in order to obtain the proper direction 'of drive for the milling machine as designed. The crossing of a belt creates a nuisance and there may be installations where the distances between shafts are too Short for running crossed belts. A machine might also, by reason f carelessness, be set up so that it, or parts of it, might be broken by running the machine in the wrong direction.J Y It is an object` of this invention to provide a machine in which parts cannotk be run in a wrong direction. s

Referring to the drawings, the reference numeral 1 designates a milling machine generally. The reference numeral 2 desigfingv and is prevented from endwise move- Pa'rl-:N'r Y OFFICE.

WISCONSIN, AssIGNon To XEARNEY a,

onenmza'rron.

1925. Serial No. 46,787.

nates a base, 3 a column, 4a vertically mov-` able knee, 5 a saddle slidable upon the knee 4, and 6 a table slidable upon the saddle 5. The

column 3 is illustrated as provided with an overarm 7 and with a spindle 8. The conis illustrated as keyed to a shaft 11 by akey 12.

The shaft 11 is provided with av reduced part 13 upon which the driving pulley 10 is seated and upon which it is retained 4by the nut 14 screwed onto theouterscrewthreaded end of the shaft. The shaft 11 can rotate in a bearkn ment by the driving pulley 1() and by a gear 16 which is secured by a pin 17, for example,

to,l the4 shaft. The shaft 11 has secured to its inner end one member 18 of. afriction clutch 19. A shaft 20 is supported near one end in a bearing 21 and its other end `is provided with a reduced cylindrical part 22 which is supported in a bearing 23 formed in the inner end of the shaft llso that the shaft 11 can rotate without rotating the shaft 20. A vcombined clutch and brake member 24' is supported by the shaft .20 and is movable longitudinally thereof by means of the shipping lever 25 which ispivoted to the column 3 by the ,pivot '26. The shipping lever 25 engages with a circumferential groove L27 in the c0111-, bined clutch and brake member 24 in an ordinary manner, Aand' the combined clutch and brake member 24 and the shaft 20 are com?, e

pelled to rotate together by a key 28, aipart -of which iis-seated in the shaft 20 andthe other part of which extends into a longitudinal keyway 29 in the combined clutch and brake member 24. The combined clutch and brake member 24 is provided with a member 100 30 of the friction clutch 19 to coact withthe member 18 of this friction clutch, the two members bein provided with coactin coned parts, aswwill vereadily understoody rom an inspection of Fig. 1 of the drawings. vAn 105 to constitute a brake for stopping the niovements of parts when the two members of the friction clutch 19 are disengaged by the shipl ping lever 25. The shaft 20 has'a bevel gear 320 rigidly secured thereto so as to rotate therewith, this point being accentuated by ,Y Fig. 1 of the drawings showing the bevel gear 320 as an integral part of the shaft 20. The bevel gear 320 meshes with a bevel gear 33 .which is rigidly secured to a shaft 34. A

the drawings. Ashaft 36 is supported in .a-

bearing 37 at one end and has a reduced cylindrical part 38 whichy fits in a cylindrical v bearing 39 in the end ofthe shaft 2().\` The bevel gea-r 35 is loose upon the Ishaft 36H while the gear 4() is secured to the shaft 36 so as to rotate therewith and the clutch memc ber 41 is alsosecured to the shaft 36 so as to rotate therewith while being longitudinally movable thereon by means of the shipping lever 42 which is pivoted on the pivot 43. Fig. 1 of the drawings illustrates the clutch member 41 as provided with a circumferential groove 44 for the shipping lever 42, this construction being common and the same as the construction for the shippinglever 25 and the `circumferential groove 27 of the combined clutch and brake member 24. The clutch member 41 and the bevel gears 320 and 33 are illustrated as provided with clutch teeth which, when they coact or engage, will not become disengaged except byv moving the clutch member 41 by the rshipping lever 42. The clutch member 41 is provided with two sets of clutch teeth which are designated by the reference numerals 45 and 46, and the bevel gears 320and 35 are provided with clutch teeth 47 and 48 and it will be readily apparent from an inspection of Fig. 1 of the drawings that, when the clutch teeth 45 and 47 are intermeshed and coacting, thev shaft 36 can be rotated directly by the shaft 20 and in the same direction of rotation with the shaftQQ, while, if the clutchteeth 46 and 48 be engaged or coacting, the shaft 36 can be rotated by the shaft 20, but the direction of rotation of the shaft 36 will be opposite to the direction of rotation of the shaft 20. This action results from the shaft 20 beinfra drive shaft with'the bevel gear 320 rigidlyxed therewith so that the shaft 36 will be driven by the shaft 2O when the clutch teeth 45 of the clutch member 41 are engaged with the clutch teeth 47 of the bevel gear 320. If, however,the clutch member 41 be moved so that its clutch teeth 46 engage the clutch -teeth 48 of the bevel gear 35 which is loose on the shaft 36,

the shaft 36 will be driven from the shaft 2O through thegbevel gear 320, the bevel gear 33,

the bevel gear 35, the clutch member 41, and

the key 49 which secures the clutchmember 41 tothe shaft 36` to compel rotation of the clutch member 41` and the shaft 36 together while permitting the clutch member 41 to be movedlongitudinally on the shaft 36. The

total length of the clutch member 41 and itsV clutch teeth 45 and 46 is less than the dis tance between the clutch teeth 47 on the bevel gear 320 and the clutch teeth 48 on the bevel gear 35,`so that the clutch member 41 can be moved by the shipping lever 42 into positions to engage either the clutch teeth of the bevel gear 320 or the clutch teeth of the bevelgear 35 or to occupy a neutral position without engaging the clutch teeth of either of said bevel gears. The gear 40 drives the spindle 8 and the tool arbor and tool or tools, not shown, by 'means of a gear 50, whichr is rigidly secured to the spindle 8, and gears 51 and 52 which are illustrated by the drawings as rigidly secured to a shaft 53.

The operation of the mechanism as thus Ifar described will be readily apparent from an inspection of Fig. 1 of the drawings. suming that the belt pulley 10 is being rotated in .either of its two possible directions of rotation, and assuming that the members 18 and .x

30 of the friction clutch 19 are engaged and coacting, the shaft 36 will be rotated if the clutch teeth on the clutch member -41 are engaged with either the clutch teeth 47 on the bevel gear 320 or with the clutch teethv48 on the bevel rear 35. It will also be readily apparent, on account of the relationship of the bevel gears `320, l33, and 35, the bevel gear 35 being loose on the shaft 36, that the direction of rotation of the shaft 36 will depend lsolelylupon the position of the clutch member 41, and that the direction of rotation of the spindle 8 will lbe solely dependent upon the position of the clutch member 41. This construction, therefore, provides for the spindle 8 being rotated in either direction no matter what may be the direction of rotation of the pulley 10, the shaft 11, and the shaft 2 0. In other words, the operator of the machine always has under his control the direct or the reverse motion of the tool, not shown,

,l driven by the spindle 8. The words direct and reverse may be referred to a direction of movement of the table 6, to make theirmeanings clearer. It ispreferred that the direction of rotation of the spindle 8 of a milling machine shall be left entirely to the contro of an operator insteadof being either vnotl subject to his control or only partially subject yto his control, but there are other parts of the mechanism which it is desirable shall not be' subject to the operator-s control at all, while there are other parts of mechanism which it is desirable to have automatically operated in a predetermined manner,

.in whatever direction the main drive may rotate, but which are also under the control of the operator, as will nowbe described.

The reference numeral 54 designates a Asl iyriaeis A reservoir lor lubricant. The lubricant is lll x the parts is determined by bolts 9i.

pumped trom the reservoir 5l by a unidirectional pump 56, such as a gear pump, and is distributed by conduit connections 57 and retnrns to the reservoir 54 by gravity. The unidirectional pump 56 may be et any snit able or preferred construction, but Fig. l of the drawings illustrates a pump of the inter meshing gear type provided with tivo gears 5d ando@ which rotate together but in oppo- Site ydirections oit rotation, the gear 5S beingl rigid with a` shalt 6() to which a gear l 1s also rigidly connected. The Igear 6l meshes with a gear b2 which may be formed integrally 1with the bevel gear 63, the point beingl to have the gear 62 and the bevel gear Gil connected together and both loose on the shalt tiel. ythe bevel rear 63 is always in mesh with a bevel gear thi which is rotatable on a stud lili, and the bevel gear 65 is always in mesh with a bevel rear 6'( which is also loose npon theshatt tiel. rlhe shaft tS-l is rotated by the gear 16 by means ot the Anears G8 and 69. The crear till is tired to the shaft 6ft so as to pro doce rotation o'l the shaft tbl While permitting longitudinal movement ot theshaft lill' with respect thereto., lFig. l of the drawings illustrates a lrey seated in lthe shaft (i4 and ,extending into a keyway 71 in the gear 'l`he bevel gears 63 and (i7 are provided with clutch teeth 72 and *(3 which face in opposite directions and have drive laces 74 and 75 and disengaging faces 7 6 and 77 to coaet with drive laces 78 and 79 and disengaging :laces 80 and 8l of clutch teeth 82 and 83 on a clutch member 84 which is secured to the shaft G/l in any suitable manner as, for example, by a pin 85 extending through the clutch niember 84 and the shalt 64. The clutch member 8l is illustrated by the drawings as composed ot tvvo parts 86 and 87. The part 86 is i1lnstrated as secured to the shatte by the pin 85 and is provided with drive lugs 88 which en gage in recesses 89 in the part 87. The parts 86 andl" are resiliently separated by springs 90 and the 4permissible limitof separation of The reason tor the resilient connection of the parts is to permit the clutch teeth of the clutch member 84 to properly engage the clutch teeth on a bevel gear '63 or 67 when the clutch member dl is moved with the shalt 64 te disengage the clutch member trom one bevel gear and to engage With the other bevel gear in the manner to be presently described, as the points ol clutch teeth on the clutch member @l might be brought into contact with the points et clutch teeth on a bevel gear during?,

liti

'thevmovement ot parts. Should the points ot the clutch teeth contact, the springs 9() vvill yield until the clutch teeth are brought into positions for proper engagement, when the springs 90 will cause the proper engagement of the clutch, teeth.

Assuming, tor example, that the belt 9 is intended to rotate the belt pulley 10 in a clockwise direction but that, forsome reason, the belt pulley l0, or the main drive is rotated in a countercloclrwise direction, these directions being determined by a person facing the machine and the pulley 10. The ,shalt ll and the gear ltlvvill be rotated countercloclwise; the gear 68 will be rotated clockwise; the gear 69, the shaft 64, and the clutch member 84 will be driven counterclock- Wise. The mechanism ol the vpump 56 ollers enough resistance, combined With other `frictional resistance, to prevent the pump mechamsm beingr driven when the disengagine; laces 8U ot the clutch teeth 82 of the clutch member 84 are attempting to drive the bevel lgear 67 by engaging the disengaging faces gg ot the clutch teeth i3 on the bevel gear G7 is always thro-ugh the shaft 64 and the clutch i'nember 84, and, looking at Fig. 2 of the drawings, it will be readily seen that, it' the shaft 64 and the clutch member 84 are rotated in a counter-clockwise direction, the clutch member 84; and the shaft 64 Will be moved bodily towards the left hand with the result that the clutch teeth 83 on the clutch member 8d will engage the clutch teeth 72 on the bevel gear 63 and rotate the bevel gear 63 connterclockwise. It the clutch member S4 were driving the bevel gear 67 in a clockwise direction, the direction of rotation ot the bevel gear 63 would be in acounterclockwise direction on account of thepresence of the bevel gear G5. It Will thus be apparent that the gear 6l and the pump gears 58 and 59 Will always be driven in the same direction regardless ot the direction of rcitation of the shaft 64, and that no attention need be given to the lubricant pump and its driving con-l nections to prevent damage or inoperativeness 1n ease ola reversal of the direetion'ot The drive onto the bevel gears 63 and rotation of the main drive, or belt pulley 10 .l

,shalt 95. d ,clntch member 96 is secured to the shaft by a pin 97 and this clutch mem- "ber @das illustrated by the drawings, is off the same construction in all respects, with the exception of the facing ot the clutch teeth on its ends, as the clutch member 84 alreadyy de scribed. lt will be noted that the clutch teeth ot the clutch member 84 i'aee in opposite directions While the clutch teeth of the clnteh member 96 tace in the same direction. The reasonflor this diiierenee in construction is due to the tact that the clutch member S4 is the driving member While the `clutch member 96 is a driven member. The clutch teeth on the bevel gear 93 are designated by the ret- 4erencel numeral 98 While the coasting clutch by the reference numeral 99; and the clutch 'construction' as teeth on the bevel gear 94 are designated by the reference numeral 100 while the coacting clutch teeth on the clutch member 96 are designated by the reference numeral 101. These several clutch teeth have drlive faces and disengaging faces'of the same construction and for the same purpose as the corresponding clutch teeth of the clutch member 84 and the bevel gears associated therewith, with the eX- ception as to the direction of facing of the clutch teeth as hereinbefore noted,and does not require any further description here. The shaft 95 is endwise movable and has rigidly secured thereto a gear 102 and a gear 103.

. The gear 103 is shown by Fig. 1 of the drawings as driving a gear 104, a shaft 105, gear 106gear 107 which are change speed gears, Shaft 108, universally jointed and telescopically constructed shaft 109, and shaft 110.

rIhe gear 102 meshes with a gear 111 which l is secured to a shaft 112. The fshaft 112 opf erates a nonreversible pump 113, which is illustrated by Fig. 1 ofthe drawings as a gear type of pump which is of the same type of the pump 56 heretofore described and which has a gear 114 secured to 'thefshaft 112 and a gear 115 meshing with the gear 114. The reference numeral 116 designates a reservoir for a lubricant or cooling liquid for a cutting tool, not shown, and this liquid 117 is pumped by the pump 113 through suitable conduits 118 to the piace of use.

Fig. 1 of the drawings shows the parts in positions 4to be of the belt pulley1 10 and the shaft 11 and, as-

suming that the belt`pulley 10 is being rotated, the'bevel gear 92 lis rotating the bevel' gear 94 to rotate the shaft 95 in a counter l clockwise direction. If, for any reason, lthe main drive isgcounter-clockwise, the clutch `member 96 and 4 shaft 95 will be moved ltowards the left and the clutchm'ember 96 will engage the clutch teeth 98 on the bevel gear 93 and the shaft 95 will'V still be rotateda counterclocltwis'e direction and the direction iof rotation of the gears and shafts driven `from the shaft will not be affected by any change in the direction of rotation of the pulley 10er shaft 11.

The shaft 110 transmits different velocities the positions of the gears' f the speed change mechanism. The particular speed for the movement of the table 6' is selected, within according to the metal being worked and according to the thickness yof the cut being taken, but it isdesirable to return the specifically described hereafter. A gear 119 is loosely mounted upon the shaft 110 and isV provided with clutch teeth 120. clutch driven by a clockwise rotation clutch-teeth 9.9 on' the' member 135 is provided with member 121 is mounted on the shaft 110 so as to be rotated thereby but being `free to be moved longitudinally thereof. The clutch member 121 is provided with clutch teeth 122 j the shaft 110. It will be readily seen from an inspection of Fig. 1 of the drawings that the gear 119 can be clutched to the shaft 110 or unclutched therefrom by the proper movement ofthe clutch member 121. The gear 119 meshes with a gear 126, which is fast upon a shaft 127 and upon-which shaft a bevel gear 128' is alsofast. The bevel gear 128 meshes with a bevel gear 129 which is fast to a shaft 1 30 to which another bevel gear 131 is also fast. The reference iiumeral 132 designates the feed screw for the table 6. This feed -screw 132 is provided with a longitudinal groove v133 to receive a spline 134 on a clutch member-135. The clutch member 135 is provided with clutch teeth 136 and 137 at oppo- 'site ends to engage respectively with clutch teeth 138 and 139 on bevel gears 140 and 141 through which the feed screw 132 passes freely. -These bevel gears 140 and 141 are constantly in mesh with the bevel gear 131 and are suitably supported by the saddle 5 for rotation and constant engagement with the bevel gears 140 and 141., The screwthreaded part ofthe feed screw 132 passes through a screwthreaded nut 142 which is secured to the saddle 5 by a pin 143, for example, to hold it fixed against rotation. The feed screw 132 is illust-rated by Fig. 5 of the drawings as provided with a reduced part 144 which is rotatable in a bearing 145 in the table 6 and is provided with a shoulder 147 to move the table in one direction while a collar 147 se cured to thefeed screw by a pin 148 moves the table'in the opposite direction. The clutch a circumferential groove 149'for a shippinv lever 150 and the length of the clutch member 135, includ- -ing lthe clutch ,teeth'thereom is less than the ,move the .clutch member 135 to clutch the feed screw 132 to either the bevel gear 140 or to ies l l the bevel .gear 141 or move it to an intermci 'of movement to the `table 6 in'accordance with f diate or neutral position in which the clutch member is not engaged with either of said bevel gears. The construction and operation o'f the feed screw 132 andfits immediately asthe range of adjustment of the speed change gears,

sociated mechanisms just described is an orc d'inary and well-known construction on millying machines, foreXample, and will be readily'understod, but it should be observed that the presence of the automatically acting clutch member 96 has retained and preserved for tl- .i operator' of the machine the customary right and left vmovementsof the shipping lever 150 for the feeding movement of the table and its 'return movement no matter in what direction the main drive, the shaft 11 tor example, may be rotated, so that the opcrater is not disturbed and continues to control the movements oit the table 6 in precisely CFI the same manner to which` he has become accustomed and his etliciency as a millino' machine operator is not impaired by the direction ot rotation ot the main drive of the millingl machine as a unit.

1t is very desirable in the operations ot certain classes of machines to provide tor a return or non-working movement to be much faster than a working movement in order to eliminate what may properly be termed idle time of the machine and idle time of the operatoror operators of the machine. Such a quiclr movement ot the table 6 can be easily accomplished with my invention, Without changing ordinary and` well-known movements of the operator in controlling amachine, by taking a drive trom some part ot' the machine the direction of motion of which' is not changed by a change of direction of motion of the main drive. As heretofore eX- piained, thedirection ot rotation ot the gear .11 and the reference numeral 151 (see Fig. 6

ot the drawings) designates a gear which meshes with the gear 62. This gear 151 is not seen in Fig. 1 of the drawing :tor the reason that it happens to be placed in front of the gear 62 and is eliminated by the sectional showing of Fig. 1 of the drawings, but its location is plainly shown by Fig. "6 of the drawings; The gear 151 is fast on a shaft 152 and thelshat 152 is connected through universal joint connections and the telescopically slidable shaft 153 with ashatt 154 on which is loosely supported a gear 155 which meshes with gear 119. The gear 155 is provided with clutch teeth 156 and a clutch ymember 157, Vwhich is provided with clutch teeth 158,- is

' compelled to rotate with the shaft 154, while being longitudinally movable with respect thereto, by a key 159 which is set into the shaft 154i and extends into a leyway 160 inthe clutch member 157. The clutch member 157 is provided with a circumferential groove 161 for a clutchy shifter and a clutch shitter or shipping lever 162 is mounted on the gear boa 163 and is provi-ded with oppositely eX- tending arms' 164 and 165 which are provided vvith'projections 166 and 167 to enter the circumierential grooves 123 .and 161, respectively, ot the clutch members 121 and 157. lt will be understood that the gear box 163 is attached to the saddle 5 and that the telescopic sha'tt 109 and 153, with their universal joint connections 168, 162, 170, and 171, with the shafts to which they are connected, permit movement ot the saddle 5 towards and away from the column 6, and the vertical movements ot the lrnee d, While retaining operative drive connections between the parts,

itbeing understood, oi" course, that the parts of the shafts 109, and 153, while being erator can manipulate the clutch shifter or shipping lever 162 to either engage the clutch member'121 with the gear 119, or engage the clutch member 157 with the gear 155, o r disengage both of said clutch members from both ot said gears by proper movements of the clutch shifter or shipping lever 162 and that the movement of the clutch shifter or shipping lever 162, to eiiiect the desired results, is not dependent upon the direction of rotation of the main drive or shaft- 11. It is also obvious that the clutch members 121 and 157 cannot both be engaged with a gear at the same time.

What I claim is: 1

1. The combination in a machine tool, of a main drive capable,y of being rotated in `either direction of rotation, a spindle drive train including a reverser connected for actuation from said main drive, a part intended to be rotated in only one direction of rotation, a drive train for said part and connected to'be driven between said main drive and said reverser, and means associated with the last main drive capable of being rotated in either e direction of rotation, a rotatable par-t intended to be selectively operated in either direction of rotation, a drive train connectingr said mam drive and said part and including a selectively operable reverser, another rotatable part, a drive train for said last mentioned part and connected to be driven at a point between said main drive and said reverser, and automatic reversing means in the last mentioned train. A i

' 3. The-combinationin amachinetool, of a driver capable of being rotated in either dition of rotation of said part regardless oi.V

thedirection ot' rotation of the said driver,

rection of rotatioma part intended to be roa second part intended to be rotated in either y direction ot rotation and rotated by said first mentioned part, and a power train connecting said parts and including a selectively operable reverser.

11. The combination in a machine tool hav-` ing a rotatable spindle, of a drive train thereior including a driver capable of being rotated in either direction of rotation, clutch means in said train for connecting or disconnecting said driver and spindle, arotatable Apart intended to be rotated in only one direction of rotation, and a drive train connecting said part with the other drive train at a point between said driver and clutch means and including means to automatically maintain the single direction of rotation of said part regardless of the direction of rotation ofthefsaid driver.

v5. The combination in a machine tool, of a driver capable of being rotated in either direction ofl rotation, a tablerotatable means for imparting movementsl to said table, a drive train connecting said driver and said rotatable means including a plurality of relversers, one of which is arranged to receive and transmit power derived through the other, and means associated with said other re verser for operation thereof whenever the direction of rotation of said driver is changed.

6. The combination in a machine tool, of a main drive shaft capable of being rotated in either direction of rotati'oma pump having a rotatable part intended to be rotated' in only one direction of rotation, atable, a reverserconnected for operation of said table, a rotatable element connected forl operation both ofsaid reverser and said pump, and

means, interposed between said main drive shaft and said element, and adapted to au-v tomatically maintain unidirectional rotations of said element regardless of the direction of rotation of the main drive shaft.

7 4The combination in a machine tool, of a main drive shaft capable of being rotated in either direction of rotation, a rotatable Spindle, a spindle train connectible with said shaft and including a selectively operable reverser, a movable table, a table train connected with said spindletrain at a point between said shaft and reverser and including a'plurality of reverseis, one of which is positioned in the train to receive power through the other, and means associated with said other reverserfor operat-ion thereof Whenever the direction .of

rotation of said drive shaft'is changed.

I 8. The combination in a machine tool, of, a main drive shaft, a rotatable spindle, aI

movable table, means to rotate said spindle and to move said table from said main drive shaft, a lubricant pump having a rotatable able shaft also being provided with driving faces and disengaging faces.

9. The combination in a. machine tool, of l `driving mechanism, driven mechanism, an

mounted on said endwise movable shaft 'and provided with clutch teeth having driving and disengaging faces, a clutch member on said endwise movable shaft and composed of two members one of which is movably secured endwise movable shaft, two gears loosely.

to said endwise movable shaft while the other *l is compelled .to rotate with said shaft but is yieldingly held a predetermined distance from said first mentioned part, said clutch member being provided with clutch teeth at both ends having driving faces and disengaging faces to coact respectively with one of said gears.

10'. In a millingmachine, the combination of a spindle, ,transmission mechanism therefor including a drive pulley capable of opposite directions of rotation and a clutc operable to connect or to disconnect said spind le from said pulley, a first pump and a driving train therefor connected to be driven from said transmission between said 'clutch and said pulley, a second pump and a drivingtrain therefor connected to be driven from said transmission bet-ween'said clutch and said spindle, drive members in each of said trains movable to alternative positions, and means for automatically moving each of said members whenthe direction of rotation of said pulley is altered. Y

1In witnessavhereof ture. y

JOSEPH B. ARMITAGE.

I hereto'afx my signa- 

